In order to explore the mechanical properties and breaking behavior of pellet feed during chewing, the experiments of texture mechanics, followed by the modeling and simulation of pellet feed based on the discrete element method were carried out in this research. Five wet basis moisture contents (8%, 10%, 12%, 14% and 16%, respectively), two kinds of loading directions (L and D direction, respectively) of pig pellet feed were selected as variables. First, mechanical parameters including hardness, elasticity, tackiness and chewiness were measured by a texture analyzer. The results of compression tests showed that the hardness of pig pellet feed was 5.44-32.43 N, the elastic index was 0.04-0.94 mm, the tackiness was 0.07- 6.63 N, the chewiness was 5.52-27.39 mJ. Moreover, the hardness, tackiness and chewiness of pig pellet feed decreased significantly with the increase of moisture content but the elasticity showed an adverse varying trend. The hardness, elasticity, tackiness and chewiness along D direction outweighed that of L direction in numerical data at the same moisture content. Then, the chewing and breaking processes of pellet feed were simulated based on the discrete element method (DEM) combined with bonding particle model, in which the whole pellet feed were considered as agglomerations of micro-particles and broke when the stress between micro-particles had exceeded the maximum limit. Multi-parameter optimization experiments were carried out using quadratic orthogonal rotation design, in which stiffness coefficient (X1), critical stress (X2) and bonding radius (X3) were the influencing factors, hardness (Y1), elasticity (Y2), tackiness (Y3) and chewiness (Y4) were evaluating indicators. Based on the regression analysis of the Design-Expert 8.0.6 software and response surface analysis method, the relationship between the three influencing factors and evaluating indicators was established. The similarity between experimental and simulated results in feed morphology and mechanical index proved that the modeling method for pellet feed based on DEM was effective and accurate. This work can provide a reference for the feed forming process and the optimization design of the related feed machinery. Meanwhile, the DEM model provided a new method for evaluating the texture and palatability of pellet feed.
Keywords: discrete element method, pellet feed, texture mechanics, mechanical parameters, palatability
DOI: 10.25165/j.ijabe.20201304.5721

Citation: Peng F, Huang Z G, Fang F. Modeling and experiments of chewing mechanical properties of pellet feed using discrete element method. Int J Agric & Biol Eng, 2020; 13(4): 37–44.

discrete element method, pellet feed, texture mechanics, mechanical parameters, palatability

Information center of national animal husbandry general station, Information center of China Feed Industry Association. Development of feed industry in China in 2018. China Feed, 2019; (9): 1. (in Chinese)

Haubjerg A F, Veje C T. An experimental approach towards increasing mechanical durability of extruded fish feed in the drying process. Drying Technology, 2019; 37(11): 1418–1426.

Muramatsu K, Massuquetto A, Dahlke F, Maiorka A. Factors that affect pellet quality: a review. Journal of Agricultural Science and Technology, 2015; 9(2): 717–722.

Zeng Y, Jia F, Xiao Y, Han Y, Meng X. Discrete element method modelling of impact breakage of ellipsoidal agglomerate. Powder Technology, 2019; 346: 57–69.

Jiang L, Huang W, Liu C, Chai L, Xu Q. Microstructure, texture evolution and mechanical properties of pure Ti by friction stir processing with slow rotation speed. Materials Characterization, 2019; 148: 1–8.

Abdoulaye Hama N, Ouahbi T, Taibi S, Souli H, Fleureau J M, Pantet A. Analysis of mechanical behaviour and internal stability of granular materials using discrete element method. International Journal for Numerical and Analytical Methods in Geomechanics, 2016; 40(12): 1712–1729.

Leblicq T, Smeets B, Ramon H, Saeys W. A discrete element approach for modelling the compression of crop stems. Computers & Electronics in Agriculture, 2016; 123: 80–88.

Tamás K, Földesi B, Rádics J P, Jóri, I J, Fenyvesi L. A simulation model for determining the mechanical properties of rapeseed using the discrete element method. Periodica Polytechnica Civil Engineering, 2015; 59(4): 575–582.

Yu X. Effects of different raw materials on the quality and texture characteristics of biscuits. Modern Food, 2019; (13): 51–52. (in Chinese)

Li Y, Zhong M M, Qi B K, Zeng Q, Li H, Wang H. Effect of bio dissociation of soybean dietary fiber on texture properties of dough. Transactions of the CSAM, 2018; 49(7): 355–362. (in Chinese)

Sun Y J. Simulation of food mastication based on discrete element method. International Journal of Computer Application in Technology, 2010; 39(2): 3–11.

Sun Zhonglei. Food texture evaluation based on chewing simulation. Ph.D dissertation. Changchun: Jilin University, 2012, 05. 132p. (in Chinese)

Song X F, Zhang F W, Dai F, Zhao W Y, Yang J, Zhang X K. Parameter optimization for fertilizer block crushing device of fertilizer machine based on discrete element method. Journal of Hunan Agricultural University (Natural Sciences), 2017; 43(2): 206–211. (in Chinese)

Shi L R, Wu J M, Zhao W Y, Sun W, Zhang F W. Establishment and parameter check of farmland soil uniaxial compression model based on discrete element method. Journal of China Agricultural University, 2015; 20(4): 174–182. (in Chinese)

Liu F, Zhang J, Chen J. Modeling of flexible wheat straw by discrete element method and its parameter calibration. Int J Agric & Biol Eng, 2018; 11(3): 42–46.

Duan K, Kwok C Y, Pierce M. Discrete element method modeling of inherently anisotropic rocks under uniaxial compression loading. International Journal for Numerical and Analytical Methods in Geomechanics, 2016; 40(8): 1150–1183.

Ghodki B M, Patel M, Namdeo R, Carpenter G. Calibration of discrete element model parameters: soybeans. Computational Particle Mechanics, 2019; 6(1): 3–10.

Liu W Z, He J, Li H W, et al. Calibration of simulation parameters for potato minituber based on EDEM. Transactions of the CSAM, 2018; 49(5): 125–135, 142. (in Chinese)

Ghodki B M, Goswami T K. Thermal and mechanical properties of black pepper at different temperatures. Journal of Food Process Engineering, 2017; 40(1): e12342.1–e1342.11. doi: 10.1111/jfpe.12342.

ASAE. Wafers, pellets, crumbles-definitions and methods for determining density, durability, and moisture content. ASAE Standard S269.3, Agricultural Engineers Yearbook of Standards, 1987. 318p.

Xu Q, Tang F Y, Cheng X D. Experimental study on the relationship of compression properties of rapeseed and moisture content. Grain Science and Technology and Economy, 2017; 42(1): 32–35. (in Chinese)

Zhang Xinmu. Study on the method of determining the freshness of cold fresh meat by texture analyzer. MS dissertation. Changchun: Jilin University, 2012, 06. 93p. (in Chinese)

Zhao A L, Xue X F, Wang Y K, Ren H Y, Gong G H, Jiao J H, et al. Measuring texture quality of fresh jujube fruit using texture analyser. Journal of Fruit Science, 2018; 35(5):631–641. (in Chinese)

Wang X, Yan H L, Hou J M. Study on mechanical properties of in-situ compression and texture compaction of maize. Journal of Anhui

Agricultural Sciences, 2017; 45(11): 210–213, 249. (in Chinese)

Jia Y H, Yang X S, Xu Z, Guo Q Y, Li X Y. Effect of moisture content on the texture and chroma of lightly baked scallop. Food and Machinery, 2010; 26(3): 47–50. (in Chinese)

Ma J B, Zhang L, Wang Y, Cui W B, Wang H H, Yu Q L, et al. Analysis on correlation between change of moisture status and texture during processing of air-dried yak meat. Transactions of the CSAE, 2018; 34(7): 294–300. (in Chinese)

Zhang F W, Song X F, Zhang X K, Zhang F Y, et al. Simulation and experiment on mechanical characteristics of kneading and crushing process of corn straw. Transactions of the CSAE, 2019; 35(9): 58–65. (in Chinese)

Coetzee C J. Calibration of the discrete element method. Powder Technology, 2017; 310: 104–142.

Peng F, Wang H Y, Fang F, Kong D D. Experimental research on physical characteristics of piglet mash feed. Feed Industry, 2019; 40(7): 15–20. (in Chinese)

André D, Iordanoff I, Charles J, Néauport J. Discrete element method to simulate continuous material by using the cohesive beam model. Computer Methods in Applied Mechanics and Engineering, 2012; 213–216: 113–125.

Jin Liu. Research on analysis model and method of micro concrete. Ph.D dissertation. Beijing: Beijing University of Technology, 2014, 04. 417p. (in Chinese)